@Marks1080: More than that. Coordinating fuses or anything that uses classical over current on a transmission system is very difficult if not impossible due to the varying generation dispatch and looped nature of the system. I mean, it is technically possible
if the system was very, very meshed like a Con Edison secondary 120/208 network- every transmission line was replicated by 5-8x (if not more) and impedance was about equal between substations with load and generation evenly injected into the network, so that any short circuit on any one line resulted in the faulted line fuse seeing full fault current and all others 5-8 less fault current- so only that particular fuse would blow first and not the others. But toss in multiple contingencies and real world scenarios and watch how one could have more than one set of fuses blowing for a fault. And that is just a line. What about a buss fault at a major substation? That would be (say) 24 lines faulting at once- there will by wide spread fuse blowing on a state level- followed by the potential collapse of the system if many other lines and generators get taken out. Also think of a typical substation fed by two 3 phase lines from another substation. How do you coordinate so that a fault on any one 115kv supply line only blows the fuses associated for only that line? How do you get the 300E source fuses to blow and the 200E load station fuse to blow on any faulted line when the other line's 300E and 200E fuses see about the same current? At minimum such a setup would either require either directional over current (at the load station, distance at the supply) or ditching the 200Es at the load station and running the bus normally open.
In short selective coordination would be hit or miss. Plus the "stacking" of time current curves as you head out radially and adjusting for preloading/ambient/tolerances (further widening the gap between curves) would greatly increase the clearing time of a fault- which may exceed the critical clearing time of the system.
Second would come the nature (limitation) of changing fuses- 138kv fuses are already big enough and S&C even has a manual showing a wheel pulley to lift the fuse in place, page 5:
Mind you that is for a 250 amp 20ka fuse. The idea is that SMD fuses will protect small 0.5-30MVA transformers out on rural lines that will most likely never blow their fuse. In reality you would need 40, 63, 80 and 90ka fuses, at 2000-5000amps, though if your system is meshed for the reasons I gave above I guess you could get away with lower rated fuses. The higher interrupting would add both cost and weight if not also size. Now think of a 345, 500 or 765kv fuse... I'd imagine you would need multiple fuses rated in series for those levels because the size of one would be simply to great. Mounted high if they exhaust when clearing. A single lighting stroke would cost 10s of thousands in fuses and then a several hours of labor on top of that. Multiple strokes like those seen on Con Ed's 345kv system during some summers and you would be changing out a dozen or more bays.
Also you would still need a device to interrupt full load current- either a circuit switcher or adding SF6 interrupters to your gang disconnects. MODs to make the isolators automatic- though for remedial action, load shedding ect they may not be quick enough- so a circuit switcher would be better. But in the end a circuit switcher designed to simply interrupt load and its transients is already half way to being a live tank circuit breaker. Also in theory your fuses would still need isolators (visible gaps) on both sides when reinstalling your fuses. So nothing is saved in that regard- MODs still need a hut for power and remote control.
Finally there are 2 nightmare scenario: A major storm that results in hundreds or thousands of line trips (ie Hurricane Sandy), or even worse, a system collapse scenario. Both would result in hundreds if not tens of thousands of fuses needing to be changed. A single storm or major blackout could bankrupt a utility many times over. Also switching to save a system or isolate a collapsing one may need to interrupt current levels near that of short circuit (ie lines feeding power from a strong stable system into one that is on the verge of complete collapse or severe power swings)- requiring basically breakers.
But this isn't me coming down on you. Only thinking aloud from my understanding of why fuses aren't used more in transmission. Your idea is actually a good one- FWIW I am currently evaluating several substation designs where 34.5kv or 69kv is stepped down to 13.8kv with everything protected by load break switches and fuses. The idea is to make it mostly maintenance free and cut cost on batteries, equipment and control hut, ect. Its corny but very elegant. Reclosing is not needed since the feeds are underground. And one of these subs might even be feeding an old 4.8kv delta overhead system that had no reclosing
